EA009505B1 - A direct reduction process and apparatus - Google Patents

Abstract

A direct reduction process for a metalliferous material comprises: supplying a solid carbonaceous material and an oxygen-containing gas into a fluidised bed in a first vessel (3) and generating heat by reactions between the oxygen-containing gas and the solid carbonaceous material and any other oxidisable solids and gases in the fluidised bed and discharging a hot off-gas stream containing entrained solids; and supplying the metalliferous material to a fluidised bed in a second vessel and supplying the hot off-gas stream containing entrained solids from the first vessel to the fluidised bed in the second vessel and at least partially reducing the metalliferous feed material in the solid state in the fluidized bed and discharging a product stream of at least partially reduced metalliferous material and an off-gas stream containing entrained solids.

Description

The present invention relates to a direct reduction method and an installation for a metalliferous feed material, in particular, although not in any way exclusively, a direct reduction method and an installation for an iron-containing feed material such as iron ore.

The present invention also relates to a method for recovering a metal-bearing feed material, which includes a direct reduction method for partially recovering a metal-bearing feed material in a solid state and a melting method for melting and subsequently reducing a partially reduced metal-carrying feed material to molten metal.

The known technology of direct reduction is the so-called technology S1K.SOEEK., Which is capable of reducing the iron ore in the solid state up to 50% or more conversion into metal Eiss! Kbisbyop, 1gop up 81c1 Ephepssg. Accoaayop about £ 1gop up 81c1 Epdshssg. Rushzd, I8, yo1. 72, on. 4, 1 Arp1 1995, pp. 81-82).

S1K.SOEEK technology. based on the use of fluidized beds. The main materials loaded into the fluidized beds are fluidizing gas, metal oxides (usually iron ore fines), solid carbon-containing material (usually coal) and oxygen-containing gas (usually oxygen). The main products obtained in fluidized beds are metallized metal oxides, i.e. metal oxides that are at least partially reduced.

A significant problem preventing the industrial introduction of C1K.COEEK technology, in particular, with raw materials based on metal oxides, is that small particles of metal oxides present in the raw material can form deposits on the open surfaces of the fluidized bed unit, especially at elevated temperatures, which leads to the forced stopping of the process and cleaning the installation. In addition, degradation of resins and other volatile matter may occur, which also leads to the formation of deposits on the inner surface of the installation. These side effects limit the maximum temperature of the process, which reduces the recovery efficiency of the metal-bearing material.

The present invention is the provision of an effective method for direct reduction of metal-bearing material, which overcomes the difficulties associated with the deposition of resins and small particles of ore on the open surfaces of the installation.

The applicant has found that it is possible to efficiently and efficiently reduce iron oxides in the solid state in a two-step process, in which heat is generated by reactions between solid carbon-containing material and oxygen-containing gas in the first fluidized bed and the metal-bearing feed material is reduced in the second fluidized bed, and heat is supplied to the second fluidized bed. layer through a stream of hot exhaust gas and entrained solids from the first fluidized bed.

According to the present invention, a direct reduction method is provided for a metal-bearing material, comprising feeding solid carbonaceous material and oxygen-containing gas into a fluidized bed in the first vessel, conducting reactions between oxygen-containing gas, solid carbon-containing material and other oxidizable solids and gases in the fluidized layer to produce heat and releasing a hot stream of exhaust gas containing the solids involved, and a supply of metal-bearing material in the fabric the condition of the fluidized bed in the second vessel and the flow of hot exhaust gas containing the solids involved from the first vessel to the fluidized bed in the second vessel, at least partially recovering the metal-bearing material in the fluidized bed and releasing the product stream from at least , partially recovered metal-bearing material and waste gases containing solids involved in it.

In the above method, the functions of the heat generation and recovery process are divided into two separate vessels, which makes it possible to optimize each of these functions.

In particular, the separation of heat generation and recovery functions means that the first vessel can be operated at a high temperature to generate heat and protect itself from destruction of tar and other volatile matter, which would be possible in a situation in which heat generation and recovery occur in one vessel. Especially in situations where heat generation and recovery occur in a single vessel, the possibility of the formation of deposits with metal-bearing materials limits the maximum operating temperature that can be used.

Preferably, the method includes creating temperatures in the first vessel that are higher than operating temperatures in the second vessel.

Preferably, the method comprises carrying out the reactions in the first vessel at temperatures above 1000 ° C.

- 1 009505

Preferably, the method includes carrying out the reactions in the second vessel at temperatures below 1000 ° C.

Preferably, the method comprises feeding the oxygen-containing gas to the first vessel in a downward flow.

Preferably, the method comprises feeding the oxygen-containing gas to the second vessel in a downward flow.

More preferably, the introduction of the oxygen-containing gas into the second vessel is carried out under such controlled conditions that the desired agglomeration of smaller particles of reduced ore with other particles of the feed material occurs with the formation of larger particles of reduced ore.

Preferably, the method comprises injecting an oxygen-containing gas into the first vessel and / or into the second vessel through at least one tuyere having a tuyere head with an outlet opening located in the area of the vessel central to the side wall.

Preferably, the tuyere head is directed downwards.

More preferably, the tuyere head is directed vertically downwards.

The position of the tuyere in the vessel according to the height of the outlet of its head is determined taking into account such factors as the rate of injection of oxygen-containing gas, the pressure in the vessel, the composition and amount of other materials fed into the vessel and the density of the fluidized bed.

Preferably, the method includes water cooling the tuyere head to minimize the possibility of deposits on the tuyere head, which could block the injection of oxygen-containing gas.

Preferably, the method includes water cooling the outer surface of the tuyere head.

Preferably, the method comprises injecting the oxygen-containing gas into the vessel at a rate sufficient to form a zone substantially free of solids in the area of the tuyere head to reduce the possibility of formation of sediment on the tuyere head that can block the injection of oxygen-containing gas.

Preferably, the method includes injecting nitrogen and / or steam and / or another suitable protective gas into the vessel and protecting the outlet area of the tuyere head to minimize metal oxidation, which can lead to the formation of sediments on the tuyere head that can block the injection of oxygen-containing gas.

Preferably, the method includes controlling the temperature difference between the average temperature in the fluidized bed in the second vessel and the average temperature of the inward-facing surface of the side wall of the second vessel, so that it does not exceed 100 ° C.

The term average temperature in the fluidized bed is understood here as the average temperature throughout the fluidized bed.

More preferably, the temperature difference is not more than 50 ° C.

In the case of recovery of metal-bearing material in the form of iron ore fines, preferably the average temperature in the fluidized bed in the second vessel is maintained in the range from 850 to 1000 ° C.

Preferably, the average temperature in the fluidized bed in the second vessel is maintained at least 900 ° C, more preferably at least 950 ° C.

Preferably, the method includes controlling the temperature change inside the fluidized bed in the second vessel, so that it is not more than 50 ° C.

The temperature difference can be controlled by controlling a number of factors, including as an example the amount of solids and gases fed to the second vessel, and the choice of solids and gases.

In addition, preferably, the method includes regulating the pressure, at least in the second vessel, so that it is in the range of 1-10 bar (0.1-1 MPa) absolute pressure and more preferably 4-8 bar (0.4-0 , 8 MPa) absolute pressure.

In the case of recovery of metal-bearing material in the form of iron ore fines, it is preferable to sort the iron ore fines to a particle size of minus 6 mm.

Preferably, the iron ore fines have an average particle size in the range of 0.1-0.8 mm.

One of the advantages of this method is that it can allow for the presence of a significant amount of metal-bearing feed material with a particle size of less than 100 microns without a significant amount of this material leaving the process involved in the exhaust gas. It is believed that this is due to the agglomeration mechanism operating inside the fluidized bed, which contributes to the desired level of agglomeration between the particles of the feed material, in particular particles less than 100 microns in size, without developing unregulated agglomeration capable of interrupting the operation of the fluidized bed. Similarly, fragile ores, which tend to collapse during processing and thus increase the proportion of particles in the fluidized bed with a size of less than 100 microns, can be processed without significant loss of feed material in the exhaust gas.

Preferably, the solid carbonaceous material is coal. In such a situation,

- 2 009505 in the implementation of the method, volatile substances are removed from the coal before converting it to semi-coke (syag) and at least part of the semi-coke interacts with oxygen and forms CO in the fluidized bed in the first vessel.

Coal can be any suitable coal. As an example, coal may be coal with a medium-high volatile content, ground to a particle size of minus 6 mm.

Preferably, the fluidizing gas comprises a non-oxidizing gas.

Preferably, the fluidizing gas in the second vessel comprises a reducing gas, such as carbon monoxide and hydrogen.

Preferably, the method includes selecting the amount of hydrogen in the fluidizing gas in the second vessel, so that it is at least 10% by volume of the total volume of carbon monoxide and hydrogen in the gas.

Preferably, the method comprises separating at least partially recovered metal-bearing material and at least part of other solids (for example, semi-coke) from the product stream from the second vessel.

Preferably, the method comprises returning at least a portion of the other solids separated from the product stream to the first vessel and / or the second vessel.

Preferably, the method comprises returning at least a portion of the solids from the gas stream leaving the second vessel.

Preferably, the method includes preheating the metal-bearing material prior to loading with a gas waste from the second vessel.

Preferably, the method comprises treating the preheated off-gas to obtain a fluidizing gas and returning at least a portion of the treated off-gas to the first vessel and / or the second vessel.

Preferably, the treatment of the exhaust gas comprises one or more operations selected from the group including: (a) removal of solids; (b) cooling; (c) removal of water; (g) removal of carbon dioxide; (e) compression and (e) reheating.

Preferably, the treatment of the exhaust gas comprises returning at least a portion of the separated solids to the first vessel and / or the second vessel.

The oxygen-containing gas can be any suitable gas.

Preferably, the oxygen-containing gas comprises at least 90% by volume of oxygen.

The recovered metal-bearing material after its release from the vessel can be melted to obtain a molten metal.

According to the present invention, also provide an installation for direct reduction of metal-bearing material, which includes:

(a) a first vessel for generating a hot effluent gas stream comprising the solids involved; wherein the first vessel includes inlet means for supplying solid carbonaceous material, fluidizing gas and oxygen-containing gas to maintain the fluidized bed in this vessel and receiving a stream of hot exhaust gas containing the solids involved, and an outlet means for releasing the exhaust gas stream containing the involved solids from the vessel, and (b) a second vessel for at least partially reducing the metal-bearing material in the solid state in a fluidized bed e; moreover, the second vessel includes inlet means for feeding metal-bearing material therein, a stream of hot exhaust gas containing the solids involved, and a fluidizing gas to maintain the fluidized bed in this vessel, means for releasing it mainly a stream of solids from at least partially recovered metal-bearing material, and for discharging the off-gas stream and the solids involved from the second vessel.

Preferably, the inlet means for supplying an oxygen-containing gas to the first vessel comprises a lance having a head with an outlet opening located in the region of the vessel central to the side wall.

Preferably, the tuyere head is directed downwards in the central region of the vessel for injecting oxygen-containing gas in a downward flow.

Preferably, the tuyere head is directed vertically downwards.

Preferably, the second vessel includes an inlet means for supplying an oxygen-containing gas thereto.

Preferably, the inlet means for supplying an oxygen-containing gas to the second vessel comprises a lance having a head with an outlet opening located in the region of the vessel central to the side wall.

Preferably, the tuyere head is directed downwards in the central region of the second vessel for injecting oxygen-containing gas in a downward flow.

Preferably, the tuyere head is directed vertically downwards.

Preferably, the installation includes a means for separating the solids involved from

- 3 009505 current outgoing from the second vessel gas.

Preferably, the first vessel further comprises an inlet means for supplying solids thereto, separated in said means for separating gas from the second vessel from the stream.

Preferably, the installation includes means for treating the waste gas stream from the second vessel and obtaining at least a portion of the fluidizing gas connected to the inlet means for delivering this gas to the first vessel and / or the second vessel.

The present invention is further described with reference to the accompanying drawings.

FIG. 1 is a schematic of a plant for direct reduction of a metal-bearing feed material in accordance with the present invention, and FIG. 2 is a diagram of another embodiment of a plant for direct reduction of a metalliferous feed material in accordance with the present invention.

The following description relates to the direct reduction of metal-bearing material in the form of iron ore in the solid state. The present invention is not limited to this and extends to the direct reduction of other iron-containing materials (such as ilmenite) and, more generally, other metal-bearing materials.

The following description also relates to the direct reduction of iron ore with coal as solid carbonaceous material, oxygen as oxygen-containing gas and recycled exhaust gas containing a mixture of carbon monoxide and hydrogen as fluidizing gas. The present invention is not limited to this and extends to the use of any other suitable solid carbon-containing materials, oxygen-containing gas and fluidizing gas.

Referring to FIG. 1, the installation includes a first vessel 3, which contains a fluidized bed of gas and solids involved, and a second vessel 5, which contains a fluidized bed of gas and involved solids.

The first vessel 3 acts as a heat generator and produces a stream of hot exhaust gas including the solids involved, mainly semi-coke, which is transferred to the second vessel 5 via line 7. The purpose of the exhaust gas stream is to provide at least part of the heat required for the reactions in the second vessel .

The second vessel 5 operates as a direct reduction reactor and at least partially restores the iron ore fines in the solid state.

The second vessel forms two exiting streams.

One effluent that is discharged from the second vessel 5 through the outlet 9 at the base of the second vessel 5 comprises mainly a stream of solids from at least partially reduced iron ore fines and other solids, usually semi-coke.

The flow of solids can be treated by separating at least partially reduced iron ore fines and at least a portion of other solids. These other solids, mainly semi-coke, separated from the product stream, can be returned to the first vessel and / or to the second vessel as part of the solids that are loaded into the vessels. At least partially reduced iron ore is further processed, if required. As an example, at least partially reduced iron ore can be fed into a melting vessel based on the melting pool (LES-Laxbaxchischide SID55C1) and melted to molten pig iron, for example, by the so-called high-intensity smelting process (HFDWSS88).

The other effluent from the second vessel 5, which is discharged through the outlet 61 in the upper part of the second vessel 5, includes hot exhaust gas and the solids involved.

The waste gas stream is transferred to the cyclone 13 via line 11. Cyclone 13 separates at least part of the solids involved from the exhaust gas stream. The separated solids flow in a downward flow from the cyclone 13 through line 15 to the first vessel 3. The waste gas flows in an upward flow from the cyclone 13 to the mixing chamber 17.

The exhaust gas from the cyclone 13 is mixed with solids passing into the mixing chamber 17 of the additional cyclone 21 through line 23, and heats them. The main part of the solids in the mixing chamber 17 is drawn into the exhaust gas and passes to the cyclone 27 through line 25.

In the cyclone 27, the separation of solids and gas. The separated solids flow downwardly from the cyclone 27 through line 29 into the second vessel 5. The exhaust gas from the cyclone 27 together with the remaining solids flows in an upward flow from the cyclone 27 to the additional mixing chamber 31.

The waste gas stream from the cyclone 27 is mixed with iron ore and heats it in the mixing chamber 31. The iron ore is fed into the mixing chamber 31 through a set of 33 gate funnels. The main part of the material in the mixing chamber 31 is carried away into the cyclone 21 through line 35. As noted in detail above, the main part of the material passing to the cyclone 21 passes to the mixing chamber 17, from where it passes to the cyclone 27 and the second vessel 5 through line 29.

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The exhaust gas from the cyclone 21 is transferred via line 37 to the exhaust gas treatment unit 39 and treated in the installation as described below. Specifically, the exhaust gas is treated through a series of operations, including: (a) removal of solids; (b) cooling the exhaust gas; (c) removal of water; (g) removal of carbon dioxide; (e) compression and (e) reheating.

The treated off-gas from the off-gas treatment installation 39 becomes a fluidizing gas for vessels 3 and 5, and it is transferred to the vessels through a transfer line 41. The fluidizing gas is blown into the base of each vessel 3 and 5.

Coal with a medium-high content of volatile substances, having a particle size of minus 6 mm, is fed into the lower section of the first vessel 3 through a device for feeding solids, such as a screw-feeding device or lance 43, which pass through the side wall of the first vessel 3.

In addition, oxygen is supplied to the first vessel 3 through the lance 45, which has a tuyere head 47 extended downward with an outlet opening, which directs oxygen in a downward flow in the central zone of the first vessel 3.

As described above, the preheated iron ore is fed to the second vessel 5 via line 29, and the waste gas stream containing the solids involved is fed from the first vessel 3 to the second vessel through line 7.

In addition, oxygen is blown into the second vessel 5 through the tuyere 49, which has a tuyere head 51 extended downward with an outlet opening, which directs oxygen in a downward flow in the central zone of the second vessel 5.

The above-described supply of coal, recovered solids and fluidizing gas to the first vessel 3 forms an upward flow of fluidizing gas and entrained coal and other recycled solids in the central zone of the first vessel 3. More and more, as the particles of coal and other solids held substances move up, the particles are separated from the upward flow of the fluidizing gas and flow in a downward flow mainly in the annular region between the central region and the side wall of the first ud 3. Ultimately, these retained solids are again involved in the upward stream of fluidizing gas.

The upward flow from the fluidizing gas and the solids involved in the central region of the first vessel 3 is countercurrent with respect to the downward flow of gaseous oxygen. Some solids in the vicinity of the oxygen-containing gas stream may be entrained in the oxygen-containing gas and as a result become sticky. It is believed that the interaction of countercurrent fluidizing gas and oxygen-containing gas limits the extent to which solids that are involved in or pass through oxygen can be in contact with the surfaces of the vessel and cause the formation of deposits. It is believed that the formation of deposits is further limited due to the central location of the flow of oxygen gas within the vessel.

In the first vessel, fine coal emits volatile substances to form char, and these volatile substances from coal decompose to gaseous products (such as carbon monoxide and hydrogen). At least part of the semi-coke and volatile substances interact with oxygen and form carbon monoxide and the reaction products with volatile substances. These reactions take place with the release of substantial heat, and, as described above, heat is transferred to the second vessel 5 using a stream of hot exhaust gas containing the solids involved, which flows into the second vessel through line 7.

The above-described supply of preheated iron ore fines, a stream of hot exhaust gas containing the solids involved, from the first vessel 3, oxygen-containing gas and a fluidizing gas to the second vessel 3 forms an upward flow of gas and the solids involved in the central region of the second vessel 5. More and more more, as the solids move up, the solids are separated from the upward gas flow and flow down, mainly in the annular region between the central region and The touch the wall of the second vessel 5. Such re-circulating solids are either re-engage in the upward stream of fluidizing gas or are discharged from the vessel.

Fluidizing gas and the upward flow of solids, fluidized by fluidizing gas in the second vessel 5, are directed countercurrent to the downward flow of oxygen-containing gas. As described above with respect to the first vessel, it is believed that this countercurrent flow of fluidizing gas and oxygen-containing gas contributes to reducing the extent to which solids that are involved in or pass through the oxygen flow in contact with the surfaces of the vessel and form deposits.

The above-described supply of preheated iron ore fines, a stream of hot exhaust gas containing the solids involved, from the first vessel 3, an oxygen-containing gas and a fluidizing gas to the second vessel 5 causes the following reactions in the second vessel:

reacting at least a portion of carbon dioxide (formed during the reduction of iron ore) with carbon to form carbon monoxide (Boudoir reaction);

direct reduction of iron ore fines to at least partially reduced

- 5 009505 leza with carbon monoxide and hydrogen, and these reactions form carbon dioxide and water;

oxidation of solids and gases, such as semi-coke and particles of partially reduced metal-bearing feed material, volatile substances from coal, carried away from the first vessel 3, hydrogen and carbon monoxide in the upper section of the second vessel 5, which produces heat and contributes to controlled agglomeration of smaller particles in part reduced ore with other particles inside the fluidized bed to form larger particles of reduced ore.

The applicant does not have a completely clear understanding at this stage of the mechanism or mechanisms that allow one to achieve controlled agglomeration of the metal-bearing material, which is noted in the preceding paragraph. Despite this, not wanting to be bound by the comments below, in a research project the applicant observed that the resulting agglomerates include particles of a smaller size, in particular trifles, which stick together with each other and with larger particles. The applicant assumes that the conditions in the upper section of the vessel are such that:

(a) micron-sized particles of iron ore, partially or fully reduced, i.e. metallized, interact with oxygen and form heat and the resulting oxidized particles become sticky; (b) fine particles of coal interact with oxygen and are oxidized and the resulting ash becomes sticky; and (c) the fine iron ore particles become sticky due to the heat. The applicant also suggests that these smaller size sticky particles adhere to larger particles that have a higher heat absorption capacity; the overall favorable result is that in the vessel there is a reduction in the proportion of smaller particles that can stick to the surfaces of the installation and be carried away from the vessel in the exhaust gas stream.

The installation shown in FIG. 2 is substantially identical to the installation shown in FIG. 1, and the same reference numerals are used to describe the same features.

The main difference between the two layouts is that the installation shown in FIG. 2, does not have a tuyere for the injection of oxygen in the second vessel 5.

The reasons for eliminating the oxygen tuyere in the second vessel 5 may be the following: (a) sufficient controlled agglomeration can be achieved by blowing oxygen only into the first vessel 3, or (b) the loaded iron ore does not contain a large amount of ultrafine particles.

The embodiments of the present invention shown in FIG. 1 and 2 may have many modifications without departing from the spirit and scope of the invention.

As an example, although the first vessel 3 of each of the designs includes a lance 45, which has a tuyere 47 extended downward, which blows oxygen in a downward flow, a countercurrent upward flow of solids and a fluidizing gas, the present invention is not limited only to this design and extends to other layouts . Specifically, the present invention is not limited to blowing oxygen down through one or more than one lance 45, which has a lance 47 extended downward.

In addition, the present invention is not limited to countercurrent flows of oxygen-containing gas and solids and fluidizing gas.

Claims (44)

CLAIM 1. A method for the direct reduction of metal-bearing material, characterized in that it comprises supplying a solid carbon-containing material and an oxygen-containing gas to the fluidized bed in the first vessel, carrying out reactions between the oxygen-containing gas, the solid carbon-containing material and other oxidizable solids and gases in the fluidized bed to produce heat and the release of the stream of hot exhaust gas containing the involved solids, and the supply of metal-bearing material in the solid state in pseudo a fluidized bed in a second vessel and supplying a stream of hot exhaust gas containing the solids involved from the first vessel to the fluidized bed in the second vessel, at least partially recovering the metal-bearing material in the fluidized bed and discharging the product stream from at least partially reduced metal-bearing material and an exhaust gas stream containing solids involved. 2. The method according to claim 1, characterized in that in the first vessel create temperatures that are higher than the operating temperature in the second vessel. 3. The method according to claim 1 or 2, characterized in that the reaction in the first vessel is carried out at temperatures above 1000 ° C. 4. The method according to any one of the preceding paragraphs, characterized in that the reaction in the second vessel is carried out at temperatures below 1000 ° C. 5. The method according to any one of the preceding paragraphs, characterized in that the oxygen-containing gas is supplied to the first vessel in a downward flow. - 6 009505 6. The method according to any one of the preceding paragraphs, characterized in that the introduction of oxygen-containing gas into the second vessel is carried out under such controlled conditions that the desired agglomeration of smaller particles of reduced ore with other particles of feed material occurs to form larger particles of reduced ore. 7. The method according to any one of the preceding paragraphs, characterized in that the oxygen-containing gas is fed into the second vessel, preferably in a downward flow. 8. The method according to any one of the preceding paragraphs, characterized in that the oxygen-containing gas is blown into the first vessel and / or into the second vessel through at least one tuyere having a tuyere head with an outlet located in the region of the vessel central to the side wall of the vessel. 9. The method according to any one of the preceding paragraphs, characterized in that the lance head is directed downward, preferably vertically downward. 10. The method according to claim 8 or 9, characterized in that the position of the tuyere in the vessel by the height of the outlet of its head is determined taking into account factors such as the rate of injection of oxygen-containing gas, pressure in the vessel, composition and amount of other materials loaded into the vessel and density fluid bed. 11. The method according to any one of claims 8 to 10, characterized in that the lance head is cooled with water. 12. The method according to any one of claims 8 to 11, characterized in that the outer surface of the lance head is cooled with water. 13. The method according to any one of claims 8 to 12, characterized in that the oxygen-containing gas is blown into the vessel at a speed sufficient to form a zone substantially free of solids in the area of the lance head in order to reduce the possibility of deposits on the lance head, which can block the injection of oxygen-containing gas. 14. A method according to any one of the preceding paragraphs, characterized in that nitrogen and / or steam and / or other suitable shielding gas is blown into the vessel and protect the area of the outlet of the lance head to reduce the possibility of deposits on the lance head that may block blowing oxygen-containing gas. 15. The method according to any one of the preceding paragraphs, characterized in that the metal-bearing material and a hot stream of exhaust gas containing the involved solids from the first vessel is fed into the fluidized bed in the second vessel. 16. The method according to any one of the preceding paragraphs, characterized in that the temperature difference between the average temperature in the fluidized bed in the second vessel and the average temperature of the inwardly facing surface of the side wall of the second vessel so that it is not more than 100 ° C, preferably not more than 50 ° C. 17. The method according to any one of the preceding paragraphs, characterized in that when recovering metal-bearing material in the form of iron ore fines, the average temperature in the fluidized bed in the second vessel is maintained in the range from 850 to 1000 ° C, preferably equal to at least 900 ° C and more preferably equal to at least 950 ° C. 18. The method according to any one of the preceding paragraphs, characterized in that regulate the temperature change inside the fluidized bed in the second vessel so that it is less than 50 ° C. 19. The method according to any one of the preceding paragraphs, characterized in that they regulate the pressure in at least the second vessel so that it is in the range from 0.1 to 1 MPa (1 to 10 bar) absolute pressure and more preferably 0 , 1-1 MPa (1-10 bar) absolute pressure. 20. The method according to any one of the preceding paragraphs, characterized in that in the metal-bearing material, which is in the form of iron ore fines, the fines are sorted to a particle size of minus 6 mm. 21. The method according to any one of the preceding paragraphs, characterized in that the fines have an average particle size in the range of 0.1-0.8 mm 22. The method according to any one of the preceding paragraphs, characterized in that the carbon-containing material is coal, preferably coal with a medium high volatile matter content, milled to minus 6 mm. 23. The method according to any one of the preceding paragraphs, characterized in that the fluidizing gas comprises a non-oxidizing gas. 24. The method according to any one of the preceding paragraphs, characterized in that the fluidizing gas in the second vessel includes a reducing gas, such as carbon monoxide and hydrogen. 25. The method according to paragraph 24, wherein the amount of hydrogen in the fluidizing gas in the second vessel is chosen so that it is at least 10 vol.% Of the total volume of carbon monoxide and hydrogen in the gas. 26. The method according to any one of the preceding paragraphs, characterized in that at least partially reduced metalliferous material and at least a portion of other solids are separated from the product stream from the second vessel. 27. The method according to p. 26, characterized in that at least part of other solids, - 7 009505 separated from the product stream, is returned to the first vessel and / or to the second vessel. 28. The method according to any one of the preceding paragraphs, characterized in that at least a portion of the solids is separated from the stream of gas leaving the second vessel. 29. The method according to p. 28, characterized in that the solids separated from the exhaust stream of the exhaust gas is fed into the first vessel. 30. The method according to any one of the preceding paragraphs, characterized in that the metalliferous material is preheated prior to loading by the gas leaving the second vessel. 31. The method according to p. 30, characterized in that the preheated exhaust gas is processed to obtain a fluidizing gas, at least a portion of which is returned to the first vessel and / or to the second vessel. 32. The method according to p. 31, characterized in that the treatment of the exhaust gas includes one or more than one operation selected from the group including (a) removal of solids, (b) cooling, (c) removal of water, (d) removal carbon dioxide, (e) compression and (e) reheating. 33. The method according to p. 31 or 32, characterized in that the treatment of the exhaust gas includes the return of at least part of the separated solids in the first vessel or in the second vessel. 34. The method according to any one of the preceding paragraphs, characterized in that the oxygen-containing gas comprises at least 90 vol.% Oxygen. 35. The method according to any one of the preceding paragraphs, characterized in that the recovered metalliferous material after its release from the vessel is subjected to melting to obtain molten metal. 36. Installation direct recovery of metal-bearing material, characterized in that it includes: (a) a first vessel for generating a hot off-gas stream including solids involved, the first vessel including inlet means for supplying a solid carbon-containing material, a fluidizing gas and an oxygen-containing gas therein in order to maintain a fluidized bed in the vessel and obtain a hot off-gas stream containing the involved solids and an exhaust means for discharging from the vessel a stream of exhaust gas containing the involved solids, and (b) a second vessel for, at least at least a partial reduction of the metal-bearing material in a solid state in the fluidized bed, the second vessel including inlet means for supplying the metal-bearing material, a stream of hot exhaust gas containing the solids involved, from the first vessel and a fluidizing gas to maintain a fluidized bed in this vessel , Means for discharging therefrom a predominantly solid stream from at least partially reduced metalliferous material and for discharging the effluent stream of gas and entrained solids from the second vessel. 37. The installation according to clause 36, wherein the inlet means for supplying oxygen-containing gas to the first vessel includes a lance having a head with an outlet located in the region of the vessel central to the side wall. 38. The installation according to clause 37, characterized in that the lance head is directed downward in the central region of the vessel for blowing oxygen-containing gas in a downward flow. 39. Installation according to any one of paragraphs 36-38, characterized in that the second vessel includes inlet means for supplying oxygen-containing gas to it. 40. The apparatus of claim 39, wherein the inlet means for supplying oxygen-containing gas to the second vessel includes a lance having a head with an outlet located in a region of the vessel that is central to the side wall of the vessel. 41. Installation according to claim 40, characterized in that the lance head is directed downward in the central region of the vessel for injecting oxygen-containing gas in a downward flow. 42. Installation according to any one of paragraphs 36-41, characterized in that it has a means for separating the involved solids from the stream of gas leaving the second vessel. 43. The installation according to § 42, characterized in that the first vessel further includes an inlet means for supplying solids therein, separated in said means for separation, from a gas stream leaving the second vessel. 44. Installation according to claim 42 or 43, characterized in that it has means for processing the flow of gas leaving the second vessel and receiving at least a portion of the fluidizing gas connected to inlet means for supplying this gas to the first vessel and / or second vessel .